EC:3.6.1.25 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Target Concepts:

Query: EC:3.6.1.25 (triphosphatase)
1,529 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Baculovirus phosphatase (BVP) is a member of the metazoan RNA triphosphatase enzyme family that includes the RNA triphosphatase component of the mRNA capping apparatus. BVP and other metazoan RNA triphosphatases belong to a superfamily of phosphatases that act via the formation and hydrolysis of a covalent cysteinyl-phosphate intermediate. Here we demonstrate the formation of a BVP phosphoenzyme upon reaction with [gamma-(32)P]ATP and identify the linkage as a thiophosphate based on its chemical lability. We surmise that the phosphate is linked to Cys(119) of BVP because replacement of Cys(119) by alanine or serine abrogates phosphoenzyme formation and phosphohydrolase activity. The catalytic cysteine is situated within a conserved phosphate-binding loop ((118)HCTHGINRTGY(128)). We show that all of the non-aliphatic side chains of the phosphate-binding loop are functionally important, insofar as mutants H118A, H121A, N124A, R125A, T126A, and Y128A were inactive in gamma phosphate hydrolysis and the T120A mutant was 7% as active as wild-type BVP. Structure-activity relationships at the essential positions of the phosphate-binding loop were elucidated by conservative substitutions. A conserved aspartic acid (Asp(60)) invoked as a candidate general acid catalyst was dispensable for phosphohydrolase activity and phosphoenzyme formation by BVP. We propose that the low pK(a) of the bridging oxygen of the beta phosphate leaving group circumvents a requirement for expulsion by a proton donor during attack by cysteine on the gamma phosphorus. In contrast, a conserved aspartic acid is essential for the phosphomonoesterase reactions catalyzed by protein phosphatases, where the serine or tyrosine leaving groups have a much higher pK(a) than does ADP.
...
PMID:Mechanism of phosphoanhydride cleavage by baculovirus phosphatase. 1095 17

Saccharomyces cerevisiae RNA triphosphatase Cet1 is an essential component of the yeast mRNA capping apparatus. The active site of Cet1 resides within a topologically closed hydrophilic beta-barrel (the triphosphate tunnel) that is supported by a globular hydrophobic core. The homodimeric quaternary structure of Cet1 is formed by a network of contacts between the partner protomers. By studying the effects of alanine-cluster mutations, we highlight the contributions of two separate facets of the crystallographic dimer interface to Cet1 function in vivo. One essential facet of the interface entails hydrophobic cross-dimer interactions of Cys(330) and Val(331) and a cross-dimer hydrogen bond of Asp(280) with the backbone amide of Gln(329). The second functionally relevant dimer interface involves hydrophobic side-chain interactions of Phe(272) and Leu(273). Ala-cluster mutations involving these residues elicited lethal or severe temperature-sensitive phenotypes that were suppressed completely by fusion of the mutated triphosphatases to the guanylyltransferase domain of mammalian capping enzyme. The recombinant D279A-D280A and F272A-L273A proteins retained phosphohydrolase activity but sedimented as monomers. These results indicate that a disruption of the dimer interface is uniquely deleterious when the yeast RNA triphosphatase must function in concert with the endogenous yeast guanylyltransferase. We also identify key residue pairs in the hydrophobic core of the Cet1 protomer that support the active site tunnel and stabilize the triphosphatase in vivo.
...
PMID:Importance of homodimerization for the in vivo function of yeast RNA triphosphatase. 1127 98

Cet1, the RNA triphosphatase component of the yeast mRNA capping apparatus, catalyzes metal-dependent gamma phosphate hydrolysis within the hydrophilic interior of a topologically closed 8-strand beta barrel (the "triphosphate tunnel"). We used structure-guided alanine scanning to identify 6 side chains within the triphosphate tunnel that are essential for phosphohydrolase activity in vitro and in vivo: Arg393, Glu433, Arg458, Arg469, Asp471 and Thr473. Alanine substitutions at two positions, Asp377 and Lys409, resulted in partial catalytic defects and a thermosensitive growth phenotype. Structure-function relationships were clarified by introducing conservative substitutions. Five residues were found to be nonessential: Lys309, Ser395, Asp397, Lys427 Asn431, and Lys474. The present findings, together with earlier mutational analyses, reveal an unusually complex active site in which 15 individual side chains in the tunnel cavity are important for catalysis, and each of the 8 strands of the beta barrel contributes at least one functional constituent. The active site residues fall into three classes: (i) those that participate directly in catalysis via coordination of the gamma phosphate or the metal; (ii) those that make critical water-mediated contacts with the gamma phosphate or the metal; and (iii) those that function indirectly via interactions with other essential side chains or by stabilization of the tunnel structure.
...
PMID:Structure-function analysis of the active site tunnel of yeast RNA triphosphatase. 1127 61

The carboxyl-terminal domain (CTD) of elongating RNA polymerase II serves as a landing pad for macromolecular assemblies that regulate mRNA synthesis and processing. The capping apparatus is the first of the assemblies to act on the nascent pre-mRNA and the one for which binding of the catalytic components is most clearly dependent on CTD phosphorylation. The present study highlights a distinctive strategy of cap targeting in fission yeast whereby the triphosphatase (Pct1) and guanylyltransferase (Pce1) enzymes of the capping apparatus do not interact physically with each other (as they do in budding yeast and metazoans), but instead bind independently to the phosphorylated CTD. In vivo interactions of Pct1 and Pce1 with the CTD in a two-hybrid assay require 12 and 14 tandem repeats of the CTD heptapeptide, respectively. Pct1 and Pce1 bind in vitro to synthetic CTD peptides containing phosphoserine uniquely at position 5 or doubly at positions 2 and 5 of each of four tandem YSPTSPS repeats, but they bind weakly (Pce1) or not at all (Pct1) to a peptide containing phosphoserine at position 2. These results illustrate how remodeling of the CTD phosphorylation array might influence the recruitment and dissociation of the capping enzymes during elongation. But how does the CTD structure itself dictate interactions with the RNA processing enzymes independent of the phosphorylation state? Using CTD-Ser5 phosphopeptides containing alanine substitutions at other positions of the heptad, we define essential roles for Tyr-1 and Pro-3 (but not Thr-4 or Pro-6) in the binding of Schizosaccharomyces pombe guanylyltransferase. Tyr-1 is also essential for binding and allosteric activation of mammalian guanylyltransferase by CTD Ser5-PO4, whereas alanine mutations of Pro-3 and Pro-6 reduce the affinity for the allosteric CTD-binding site. These are the first structure-activity relationships deduced for an effector function of the phosphorylated CTD.
...
PMID:The length, phosphorylation state, and primary structure of the RNA polymerase II carboxyl-terminal domain dictate interactions with mRNA capping enzymes. 1138 25

Cet1, the RNA triphosphatase component of the yeast mRNA capping apparatus, catalyzes metal-dependent gamma-phosphate hydrolysis within the hydrophilic interior of an eight-strand beta barrel (the "triphosphate tunnel"), which rests upon a globular protein core (the "pedestal"). We performed a structure-guided alanine scan of 17 residues located in the tunnel (Ser(373), Thr(375), Gln(405), His(411), Ser(429), Glu(488), Thr(490)), on the tunnel's outer surface (Ser(378), Ser(487), Thr(489), His(491)), at the tunnel-pedestal interface (Ile(304), Met(308)) and in the pedestal (Asp(315), Lys(317), Arg(321), Asp(425)). Alanine mutations at 14 positions had no significant effect on Cet1 phosphohydrolase activity in vitro and had no effect on Cet1 function in vivo. Two of the mutations (R321A and D425A) elicited a thermosensitive (ts) yeast growth phenotype. The R321A and D425A proteins had full phosphohydrolase activity in vitro, but were profoundly thermolabile. Arg(321) and Asp(425) interact to form a salt bridge within the pedestal that tethers two of the strands of the tunnel. Mutations R321Q and D411N resulted in ts defects in vivo and in vitro, as did the double-mutant R321A-D435A, whereas the R321K protein was fully stable in vivo and in vitro. These results highlight the critical role of the buried salt bridge in Cet1 stability. Replacement of Ser(429) by alanine or valine elicited a cold-sensitive (cs) yeast growth phenotype. The S429A and S429V proteins were fully active when produced in bacteria at 37 degrees C, but were inactive when produced at 17 degrees C. Replacement of Ser(429) by threonine partially suppressed the cold sensitivity of the Cet1 phosphohydrolase, but did not suppress the cs growth defect in yeast.
...
PMID:Functional groups required for the stability of yeast RNA triphosphatase in vitro and in vivo. 1139 22

The predicted ORF3 polypeptide (Orf3p) of the linear genetic element pGKL2 from Kluyveromyces lactis was expressed in Bacillus megaterium as a fusion protein with a His(6X)-tag at the C-terminus for isolation by Ni-affinity chromatography. This is the first time that a yeast cytoplasmic gene product has been expressed heterologously as a functional protein in a bacterial system. The purified protein was found to display both RNA 5'-triphosphatase and guanylyltransferase activities. When the lysine residue present at position 177 of the protein within the sequence motif (KXDG), highly conserved in capping enzymes and other nucleotidyl transferases, was substituted by alanine, the guanylyltransferase activity was lost, thereby proving an important role for the transfer of GMP from GTP to the 5'-diphosphate end of the mRNA. Our in vitro data provides the first direct evidence that the polypeptide encoded by ORF3 of the cytoplasmic yeast plasmid pGKL2 functions as a plasmid-specific capping enzyme. Since genes equivalent to ORF3 of pGKL2 have been identified in all autonomous cytoplasmic yeast DNA elements investigated so far, our findings are of general significance for these widely distributed yeast extranuclear genetic elements.
...
PMID:Kluyveromyces lactis cytoplasmic plasmid pGKL2: heterologous expression of Orf3p and proof of guanylyltransferase and mRNA-triphosphatase activities. 1142 64

Chlorella virus RNA triphosphatase (cvRtp1) is the smallest member of a family of metal-dependent phosphohydrolases that includes the RNA triphosphatases of fungi, protozoa, poxviruses, and baculoviruses. The primary structure of cvRtp1 is more similar to that of the yeast RNA triphosphatase Cet1 than it is to the RNA triphosphatases of other DNA viruses. To evaluate the higher order structural similarities between cvRtp1 and the fungal enzymes, we performed an alanine scan of individual residues of cvRtp1 that were predicted, on the basis of the crystal structure of Cet1, to be located at or near the active site. Twelve residues (Glu(24), Glu(26), Asp(64), Arg(76), Lys(90), Glu(112), Arg(127), Lys(129), Arg(131), Asp(142), Glu(163), and Glu(165)) were deemed essential for catalysis by cvRtp1, insofar as their replacement by alanine reduced phosphohydrolase activity to <5% of the wild-type value. Structure-activity relationships were elucidated by introducing conservative substitutions at the essential positions. The mutational results suggest that the active site of cvRtp1 is likely to adopt a tunnel fold like that of Cet1 and that a similar constellation of side chains within the tunnel is responsible for metal binding and reaction chemistry. Nonetheless, there are several discordant mutational effects in cvRtp1 versus Cet1, which suggest that different members of the phosphohydrolase family vary in their reliance on certain residues within the active site tunnel. We found that tripolyphosphate and pyrophosphate were potent competitive inhibitors of cvRtp1 (K(i) = 0.6 microm tripolyphosphate and 2.4 microm pyrophosphate, respectively), whereas phosphate had little effect. cvRtp1 displayed a weak intrinsic tripolyphosphatase activity (3% of its ATPase activity) but was unable to hydrolyze pyrophosphate.
...
PMID:Chlorella virus RNA triphosphatase. Mutational analysis and mechanism of inhibition by tripolyphosphate. 1184 1

Baculovirus phosphatase (BVP) and mammalian capping enzyme (Mce1) are members of the RNA triphosphatase branch of the cysteine phosphatase superfamily. Although RNA triphosphatases have a core alpha/beta fold similar to other cysteine phosphatases, there is little conservation of primary structure outside of the cysteine-containing P-loop motif, HCxxxxxR(S/T), that comprises the active site. However, there is extensive primary structure conservation between members of the RNA triphosphatase branch, whether from cellular or viral sources and whether they are bifunctional capping enzymes such as Mce1 or monofunctional RNA phosphatases such as BVP. To evaluate the functional significance of such sequence conservation, we performed a mutational analysis of 14 residues of BVP. We identified three side chains (Trp6, Lys25, and Arg153) as essential for triphosphatase activity in vitro, i.e., W6A, K25A, and R153A were <0.1% as active as wild-type BVP, and were unable to complement a yeast RNA triphosphatase null mutant in vivo. Six other BVP residues (Thr62, Tyr67, Tyr68, Lys82, Glu158, and Arg159) were deemed functionally important, i.e., Ala mutations reduced triphosphatase activity to <20% of wild-type. On the basis of the locations of the equivalent amino acids in the Mce1 crystal structure, we surmise that the essential/important BVP residues ensure proper conformation of the catalytic P-loop (e.g., Arg153 and Tyr68) or other elements of the tertiary structure. Our results highlight a conserved Trp6-Lys25 pi-cation pair essential for BVP function.
...
PMID:Mutational analysis of baculovirus phosphatase identifies structural residues important for triphosphatase activity in vitro and in vivo. 1241 85

The 464-amino acid baculovirus LEF4 protein is a bifunctional mRNA capping enzyme with triphosphatase and guanylyltransferase activities. The N-terminal half of LEF4 constitutes an autonomous triphosphatase catalytic domain. The LEF4 triphosphatase belongs to a family of metal-dependent phosphohydrolases, which includes the RNA triphosphatases of fungi, protozoa, Chlorella virus and poxviruses. The family is defined by two glutamate-containing motifs (A and C), which form a metal-binding site. Most of the family members resemble the fungal and Chlorella virus enzymes, which have a complex active site located within the hydrophilic interior of a topologically closed eight stranded beta barrel (the so-called 'triphosphate tunnel'). Here we probed whether baculovirus LEF4 is a member of the tunnel subfamily, via mutational mapping of amino acids required for triphosphatase activity. We identified four new essential side chains in LEF4 via alanine scanning and illuminated structure-activity relationships by conservative substitutions. Our results, together with previous mutational data, highlight five acidic and four basic amino acids that are likely to comprise the LEF4 triphosphatase active site (Glu9, Glu11, Arg51, Arg53, Glu97, Lys126, Arg179, Glu181 and Glu183). These nine essential residues are conserved in LEF4 orthologs from all strains of baculoviruses. We discerned no pattern of clustering of the catalytic residues of the baculovirus triphosphatase that would suggest structural similarity to the tunnel proteins (exclusive of motifs A and C). However, there is similarity to the active site of vaccinia RNA triphosphatase. We infer that the baculovirus and poxvirus triphosphatases are a distinct lineage within the metal-dependent RNA triphosphatase family. Synergistic activation of the LEF4 triphosphatase by manganese and magnesium suggests a two-metal mechanism of gamma phosphate hydrolysis.
...
PMID:Mapping the triphosphatase active site of baculovirus mRNA capping enzyme LEF4 and evidence for a two-metal mechanism. 1259 53

The RNA triphosphatase component of vaccinia virus mRNA capping enzyme (the product of the viral D1 gene) belongs to a family of metal-dependent phosphohydrolases that includes the RNA triphosphatases of fungi, protozoa, Chlorella virus, and baculoviruses. The family is defined by two glutamate-containing motifs (A and C) that form the metal-binding site. Most of the family members resemble the fungal and Chlorella virus enzymes, which have a complex active site located within the hydrophilic interior of a topologically closed eight-stranded beta barrel (the so-called "triphosphate tunnel"). Here we queried whether vaccinia virus capping enzyme is a member of the tunnel subfamily, via mutational mapping of amino acids required for vaccinia triphosphatase activity. We identified four new essential side chains in vaccinia D1 via alanine scanning and illuminated structure-activity relationships by conservative substitutions. Our results, together with previous mutational data, highlight a constellation of six acidic and three basic amino acids that likely compose the vaccinia triphosphatase active site (Glu37, Glu39, Arg77, Lys107, Glu126, Asp159, Lys161, Glu192, and Glu194). These nine essential residues are conserved in all vertebrate and invertebrate poxvirus RNA capping enzymes. We discerned no pattern of clustering of the catalytic residues of the poxvirus triphosphatase that would suggest structural similarity to the tunnel proteins (exclusive of motifs A and C). We infer that the poxvirus triphosphatases are a distinct lineage within the metal-dependent RNA triphosphatase family. Their unique active site, which is completely different from that of the host cell's capping enzyme, recommends the poxvirus RNA triphosphatase as a molecular target for antipoxviral drug discovery.
...
PMID:Mapping the active site of vaccinia virus RNA triphosphatase. 1272 33

<< Previous 1 2 3 4 5 Next >>